Forum for Science, Industry and Business

Proteins critical to wound healing identified

19.08.2014

Mice missing two important proteins of the vascular system develop normally and appear healthy in adulthood, as long as they don’t become injured. If they do, their wounds don’t heal properly, a new study shows.

The research, at Washington University School of Medicine in St. Louis, may have implications for treating diseases involving abnormal blood vessel growth, such as the impaired wound healing often seen in diabetes and the loss of vision caused by macular degeneration.

Rei Nakamura, PhD

Pictured are normal blood vessels of a mouse’s retina.

Rei Nakamura, PhD

The mouse retina responds to injury by growing new, leaky blood vessels. This abnormal response obscures vision. The new study suggests inhibiting FGF signaling in the eye may help prevent this process.

The study appears Aug. 18 in the Proceedings of the National Academy of Sciences (PNAS) online early edition.

The paper’s senior author, David M. Ornitz, MD, PhD, the Alumni Endowed Professor of Developmental Biology, studies a group of proteins known as fibroblast growth factors, or the FGF family of proteins. FGF proteins are signaling molecules that play broad roles in embryonic development, tissue maintenance, and wound healing. They interact with specific receptor molecules, FGFRs, located on the surface of many types of cells in the body.

When an organ is injured, the healing process involves the growth of new blood vessels. Since the cells lining the interior of blood vessels and blood cells themselves are important for developing new vasculature, Ornitz and his colleagues asked what would happen if they turned off signaling of the FGFR1 and FGFR2 proteins, two major mediators of the FGF signal that are present in the cells that line blood vessels. Their strategy differed from past studies, which shut down this signaling more broadly.

“The first thing we noticed — and we were rather surprised by this — was that the mice were completely normal,” Ornitz said. “They were running around and lived to a ripe old age. We did genetic tests to make sure they actually lacked these proteins. But when we challenged these mice, we saw that they healed from a skin injury more slowly than their normal littermates, and we found that the density of blood vessels surrounding the injury site was significantly decreased.”

With collaborator and co-senior author Rajendra S. Apte, MD, PhD, the Paul A. Cibis Distinguished Professor of Ophthalmology and Visual Sciences, the investigators also looked at the eyes. Like any other organ, new blood vessels grow in the eye in response to disease or injury. But unlike the rest of the body, new blood vessels are not desired here, since they bleed, cause scar tissue formation and block light to the retina, causing vision loss.

The new work suggests that increasing FGF signaling in the body might help improve wound healing by increasing new blood vessel growth following an injury. Especially in those who have trouble healing, such as patients with diabetes-related foot ulcers. Ornitz pointed out that human FGF2 is already in clinical use as a topical spray in Japan for foot ulcers and similar wound healing purposes.

Conversely, inhibiting these pathways in the eye might help patients with age-related macular degeneration or diabetic retinopathy. Such patients grow new blood vessels in response to these diseased or injured states, but the new vessels only serve to obscure vision, not help heal an abnormal eye.

And since the research suggests these FGF pathways are not involved with normal development and tissue maintenance, any treatments boosting or inhibiting these signals would likely not effect healthy tissue.

“That’s an important point,” said Apte, who treats patients at Barnes-Jewish Hospital. “In diabetes, the normal blood vessels of the retina become fragile because the disease affects them. With any targeted therapy, we worry about damaging the normal vessels. But our work suggests that inhibiting FGF signaling in the eye may prevent this abnormal response without harming normal vessels.”

This work was supported by National Institutes of Health (NIH) grants HL105732, T32-HL07275, HL63736, HL55337, and EY019287, as well as NIH Vision Core Grant P30EY02687 and a Carl Marshall Reeves and Mildred Almen Reeves Foundation Inc. Award. This work also was supported by a Research to Prevent Blindness Inc. Career Development Award, the International Retina Research Foundation, American Health Assistance Foundation, Thome Foundation, a Lacy Foundation Research Award, a Knights Templar Eye Foundation Grant, and a Research to Prevent Blindness Inc. unrestricted grant. Transgenic mouse production was made possible through the Washington University Musculoskeletal Research Center (NIH grant P30 AR057235) and the Digestive Disease Research Core Center (NIH grant P30 DK052574).

Washington University School of Medicine’s 2,100 employed and volunteer faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is one of the leading medical research, teaching and patient-care institutions in the nation, currently ranked sixth in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.